CXCR1 Regulates Pulmonary Anti-Pseudomonas Host Defense

Pseudomonas aeruginosa is a key opportunistic pathogen causing disease in cystic fibrosis (CF) and other lung diseases such as chronic obstructive pulmonary disease (COPD). However, the pulmonary host defense mechanisms regulating anti-P. aeruginosa immunity remain incompletely understood. Here we demonstrate, by studying an airway P. aeruginosa infection model, in vivo bioluminescence imaging, neutrophil effector responses and human airway samples, that the chemokine receptor CXCR1 regulates pulmonary host defense against P. aeruginosa. Mechanistically, CXCR1 regulates anti-Pseudomonas neutrophil responses through modulation of reactive oxygen species and interference with Toll-like receptor 5 expression. These studies define CXCR1 as a novel, noncanonical chemokine receptor that regulates pulmonary anti-Pseudomonas host defense with broad implications for CF, COPD and other infectious lung diseases.

Clustered DNA damages induced by high and low LET radiation, including heavy ions

Clustered DNA damages--here defined as two or more lesions (strand breaks, oxidized purines, oxidized pyrimidines or abasic sites) within a few helical turns--have been postulated as difficult to repair accurately, and thus highly significant biological lesions. Further, attempted repair of clusters may produce double strand breaks (DSBs). However, until recently, there was no way to measure ionizing radiation-induced clustered damages, except DSB. We recently described an approach for measuring classes of clustered damages (oxidized purine clusters, oxidized pyrimidine clusters, abasic clusters, along with DSB). We showed that ionizing radiation (gamma rays and Fe ions, 1 GeV/amu) does induce such clusters in genomic DNA in solution and in human cells. These studies also showed that each damage cluster results from one radiation hit (and its track), thus indicating that they can be induced by very low doses of radiation, i.e. two independent hits are not required for cluster induction. Further, among all complex damages, double strand breaks comprise--at most-- ~20%, with the other clustered damages being at least 80%.

Characterization of thermal stability of the Escherichia coli Fapy-DNA glycosylase

Thermal stability of Escherichia coli Fpg protein was studied using far-UV circular dichroism and intrinsic fluorescence. Experimental data indicate that Fpg irreversibly aggregates under heating above 35 degrees C. Heat aggregation is preceded by tertiary conformational changes of Fpg. However, the secondary structure of the fraction that does not aggregate remains unchanged up to approximately 60 degrees C. The kinetics of heat aggregation occurs with an activation enthalpy of approximately 21 kcal/mol. The fraction of monomers forming aggregates decreases with increasing urea concentration, with essentially no aggregation observed above approximately 3 M urea, suggesting that heat aggregation results from hydrophobic association of partially unfolded proteins. With increasing urea concentration, Fpg unfolds in a two-state reversible transition, with a stability of approximately 3.6 kcal/mol at 25 degrees C. An excellent correlation is observed between the unfolded fraction and loss of activity of Fpg. A simple kinetic scheme that describes both the rates and the extent of aggregation at each temperature is presented.

Effect of single mutations on the specificity of Escherichia coli FPG protein for excision of purine lesions from DNA damaged by free radicals

The formamidopyrimidine N-DNA glycosylase (Fpg protein) of Escherichia coli is a DNA repair enzyme that is specific for the removal of purine-derived lesions from DNA damaged by free radicals and other oxidative processes. We investigated the effect of single mutations on the specificity of this enzyme for three purine-derived lesions in DNA damaged by free radicals. These damaging agents generate a multiplicity of base products in DNA, with the yields depending on the damaging agent. Wild type Fpg protein (wt-Fpg) removes 8-hydroxyguanine (8-OH-Gua), 4,6-diamino-5-formamidopyrimidine (FapyAde), and 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua) from damaged DNA with similar specificities. We generated five mutant forms of this enzyme with mutations involving Lys-57-->Gly (FpgK57G), Lys-57-->Arg (FpgK57R), Lys-155-->Ala (FpgK155A), Pro-2-->Gly (FpgP2G), and Pro-2-->Glu (FpgP2E), and purified them to homogeneity. FpgK57G and FpgK57R were functional for removal of FapyAde and FapyGua with a reduced activity when compared with wt-Fpg. The removal of 8-OH-Gua was different in that the specificity of FpgK57G was significantly lower for its removal from irradiated DNA, whereas wt-Fpg, FpgK57G, and FpgK57R excised 8-OH-Gua from H2O2/Fe(III)-EDTA/ascorbic acid-treated DNA with almost the same specificity. FpgK155A and FpgP2G had very low activity and FpgP2E exhibited no activity at all. Michaelis-Menten kinetics of excision was measured and kinetic constants were obtained. The results indicate an important role of Lys-57 residue in the activity of Fpg protein for 8-OH-Gua, but a lesser significant role for formamidopyrimidines. Mutations involving Lys-155 and Pro-2 had a dramatic effect with Pro-2-->Glu leading to complete loss of activity, indicating a significant role of these residues. The results show that point mutations significantly change the specificity of Fpg protein and suggest that point mutations are also expected to change specificities of other DNA repair enzymes.

The HAP1 protein stimulates the turnover of human mismatch-specific thymine-DNA-glycosylase to process 3,N(4)-ethenocytosine residues

When present in DNA, 3,N(4)-ethenocytosine (epsilon C) residues are potentially mutagenic and carcinogenic in vivo. The enzymatic activity responsible for the repair of the epsilon C residues in human cells is the hTDG protein, the human thymine-DNA-glycosylase that removes thymine in a T/G base pair [Proc. Natl. Acad. Sci., U.S.A., 95 (1998) 8508]. One of the distinctive properties of the hTDG protein is that it remains tightly bound to the AP-site resulting from its glycosylase activity. In this paper we report that the human AP endonuclease, the HAP1 (Ape1, APEX Ref-1) protein, stimulates the processing of epsilon C residues by the hTDG protein in vitro, in a dose-dependent manner. This property of HAP1 protein is specific since E.coli Fpg, Nfo and Nth proteins, all endowed with an AP nicking activity, do not show similar features. The results suggest that the HAP1 protein displaces the hTDG protein bound to the AP-site and therefore increases the turnover of the hTDG protein. However, using a variety of techniques including gel retardation assay, surface plasmon resonance and two-hybrid system, it was not possible to detect evidence for a complex including the substrate, the hTDG and HAP1 proteins.

Recognition and kinetics for excision of a base lesion within clustered DNA damage by the Escherichia coli proteins Fpg and Nth

Ionizing radiation and radiomimetic anticancer agents induce clustered DNA damages that are thought to lead to deleterious biological consequences, due to the challenge that clustered damage may present to the repair machinery of the cell. Specific oligonucleotides, containing either dihydrothymine (DHT) or 7,8-dihydro-8-oxoguanine (8-oxoG) opposite to specific lesions at defined positions on the complementary strand, have been used to determine the kinetic constants, K(M), k(cat), and specificity constants, for excision of DHT and 8-oxoG by the Escherichia coli base excision repair proteins, endonuclease III (Nth) and formamidopyrimidine glycosylase (Fpg), respectively. For excision of DHT opposite to 8-oxoadenine by Nth or Fpg proteins, or 8-oxoG opposite to 8-oxoG by Fpg, the major change in the specificity constant occurs when the second lesion on the complementary strand is one base to the site opposite to DHT or 8-oxoG. The specificity constants for excision of DHT or 8-oxoG by both proteins are reduced by up to 2 orders of magnitude when an abasic site or a strand break is opposite on the complementary strand. Whereas the values of K(M) are only slightly affected by the presence of a second lesion, the major change is seen as a reduction in the values of k(cat). The binding of Fpg protein to oligonucleotides containing 8-oxoG is inhibited, particularly when a single strand break is near to 8-oxoG on the complementary strand. It is inferred that not only the binding affinity of Fpg protein to the base lesion but also the rate of excision of the damaged base is reduced by the presence of another lesion, particularly a single strand break or an AP site on the complementary strand.

Clustered DNA damages as dosemeters for ionising radiation exposure and biological responses

Clustered DNA damages--two or more lesions (oxidised bases. abasic sites, or strand breaks) within a few DNA helical turns on opposing strands--are induced in DNA in solution and in vivo in human cells by ionising radiation. They have been postulated to be difficult to repair, and thus of potentially high biological significance. Since the total of clustered damages produced by ionising radiation is at about 3 to 4 times higher levels than double-strand breaks and are apparently absent in unirradiated cells, levels of clustered damages present immediately alter radiation exposure could serve as sensitive dosemeters of radiation exposure. Since some clusters may not be repairable and may accumulate in cells, they might also be useful as integrating dosemeters of biological effects of radiation damage.

Frequencies and relative levels of clustered damages in DNA exposed to gamma rays in radioquenching vs. nonradioquenching conditions

Clustered damage induced by ionizing radiation--two or more oxidized bases, abasic sites, or strand breaks within a few DNA helical turns--have been postulated to be major lethal and/or mutagenic sites. Although they have recently been shown to be induced in genomic DNAs by ionizing photons and particles, little is known of the factors that affect their yields or the relative levels of the classes of clusters. Toward this aim we have investigated the effect of DNA milieu, specifically, a nonradioquenching (phosphate) or radioquenching (Tris) solution, upon the generation of clustered lesions in a well-defined molecule, T7 bacteriophage DNA. Irradiation of DNA in Tris reduces the yields of all clustered damages to 1-3% of the levels formed in phosphate. Further, although the percentage of the total clusters in oxidized purine clusters is largely unchanged, and the level of abasic clusters decreases, the frequencies of double-strand breaks and oxidized pyrimidine clusters increase in the radioquenching solution. The ratio of the level of oxidized pyrimidine clusters to double-strand breaks in a DNA in radioquenching solution is similar to that obtained in DNA in human cells, also a radioquenching environment.

Fusion of chromatophores from photosynthetic bacteria with a supported lipid layer: characterization of the electric units

Direct electrometric measurements of membrane potential changes are a valuable tool for study of vectorial transfer of electrons, protons, and ions. Commonly model membrane systems are created by fusion of lipid/protein vesicles with lipid-coated thin films. We characterized the electric units resulting from this process using chromatophores from the purple bacterium Rhodobacter sphaeroides and either a Mylar film or a planar modified gold electrode as support. Investigation of the shunting activity of the ionophore gramicidin on the flash-induced potential change demonstrates fusion of individual chromatophores to form independent 'blisters', which preserve an interior aqueous compartment. Under current-clamp conditions the photovoltage follows the change of the membrane potential of the individual blisters.

AlkA protein is the third Escherichia coli DNA repair protein excising a ring fragmentation product of thymine

Various forms of oxidative stress lead to the formation of damaged bases including N-(2-deoxy-beta-D-erythro-pentofuranosyl)-N-3-(2R-hydroxyisobutyric acid)-urea or alphaRT, the fragmentation product of thymine formed from 5R-thymidine C5-hydrate upon hydrolysis. It was shown that alphaRT is excised by Escherichia coli Fpg and Nth proteins. Here we report that when present in DNA, alphaRT is, in addition, a substrate for the E. coli AlkA protein with an apparent K(m) value of congruent with170 nM. alphaRT positioned opposite T, dG, dC, and dA were efficiently excised by AlkA protein from duplex oligodeoxynucleotides in the following order: dA approximately T >> dC approximately dG. This is the first example of the excision of a ring opened form of a pyrimidine by AlkA protein and also the first example where the same DNA base lesion is excised by three different DNA glycosylases of the base excision repair pathway. The present results suggest possible structural similarity of the active site between E. coli AlkA, Fpg, and Nth proteins.

Comparison of the levels of 8-hydroxyguanine in DNA as measured by gas chromatography mass spectrometry following hydrolysis of DNA by Escherichia coli Fpg protein or formic acid

8-hydroxyguanine (8-OH-Gua) is one of many lesions generated in DNA by oxidative processes including free radicals. It is the most extensively investigated lesion, due to its miscoding properties and its potential role in mutagenesis, carcinogenesis and aging, and also to the existence of analytical methods using HPLC and gas chromatography mass spectrometry (GC/MS). Some studies raised the possibility of artifacts generated during sample preparation. We investigated several experimental conditions in order to eliminate possible artifacts during the measurement of 8-OH-Gua by GC/MS. Derivatization has been reported to produce artifacts by oxidation of guanine to 8-OH-Gua in acid-hydrolysates of DNA, although the extent of artifacts seems to depend on experimental conditions. For removal of 8-OH-Gua from DNA, we used either formic acid hydrolysis or specific enzymatic hydrolysis with Escherichia coli Fpg protein. Derivatization of enzyme-hydrolysates should not generate additional 8-OH-Gua because of the absence of guanine, which is not released by the enzyme, whereas guanine released by acid may be oxidized to yield 8-OH-Gua. The measurement of 8-OH-Gua in calf thymus DNA by GC/isotope-dilution MS (GC/IDMS) using these two different hydrolyses yielded similar levels of 8-OH-Gua. This indicated that no artifacts occurred during derivatization of acid-hydrolysates of DNA. Pyridine instead of acetonitrile and room temperature were used during derivatization. Pyridine reduced the level of 8-OH-Gua, when compared with acetonitrile, indicating its potential to prevent oxidation. Two different stable-isotope labeled analogs of 8-OH-Gua used as internal standards for GC/IDMS analysis yielded similar results. A comparison of the present results with the results of recent trials by the European Standards Committee for Oxidative DNA Damage (ESCODD) is also presented.

Clustered damages and total lesions induced in DNA by ionizing radiation: oxidized bases and strand breaks

Ionizing radiation induces both isolated DNA lesions and clustered damages-multiple closely spaced lesions (strand breaks, oxidized purines, oxidized pyrimidines, or abasic sites within a few helical turns). Such clusters are postulated to be difficult to repair and thus potentially lethal or mutagenic lesions. Using highly purified enzymes that cleave DNA at specific classes of damage and electrophoretic assays developed for quantifying isolated and clustered damages in high molecular length genomic DNAs, we determined the relative frequencies of total lesions and of clustered damages involving both strands, and the composition and origin of such clusters. The relative frequency of isolated vs clustered damages depends on the identity of the lesion, with approximately 15-18% of oxidized purines, pyrimidines, or abasic sites in clusters recognized by Fpg, Nth, or Nfo proteins, respectively, but only about half that level of frank single strand breaks in double strand breaks. Oxidized base clusters and abasic site clusters constitute about 80% of complex damages, while double strand breaks comprise only approximately 20% of the total. The data also show that each cluster results from a single radiation (track) event, and thus clusters will be formed at low as well as high radiation doses.

Novel substrates of Escherichia coli nth protein and its kinetics for excision of modified bases from DNA damaged by free radicals

Escherichia coli Nth protein (endonuclease III) is a DNA glycosylase with a broad substrate specificity for pyrimidine derivatives. We discovered novel substrates of E. coli Nth protein using gas chromatography/isotope-dilution mass spectrometry and DNA samples, which were damaged by gamma-irradiation or by H(2)O(2)/Fe(III)-EDTA/ascorbic acid. These were 4, 6-diamino-5-formamidopyrimidine, 5,6-dihydroxyuracil, and 5, 6-dihydroxycytosine. The first compound was recognized for the first time as a purine-derived substrate of the enzyme. We also investigated kinetics of excision of a multitude of modified bases from three damaged DNA substrates. Excision of modified bases was determined as a function of enzyme concentration, incubation time, and substrate concentration. Excision followed Michaelis-Menten kinetics. Kinetic parameters were determined for the following modified bases: 4,6-diamino-5-formamidopyrimidine, cis- and trans-thymine glycols, 5-hydroxycytosine, cis- and trans-uracil glycols, 5-hydroxyuracil, 5-hydroxy-5-methylhydantoin, alloxan, 5, 6-dihydroxycytosine, 5,6-dihydroxyuracil, 5-hydroxy-6-hydrothymine, and 5-hydroxy-6-hydrouracil. The results show that three newly discovered substrates were excised by the enzyme with a preference similar to excision of its known major substrates such as thymine glycol and 5-hydroxycytosine. Excision kinetics significantly depended on the nature of the damaged DNA substrates in agreement with previous results on other DNA glycosylases. Specificity constants (k(cat)/K(M)) of E. coli Nth protein were compared to those of its previously investigated functional homologues such as human and Schizosaccharomyces pombe Nth proteins and Saccharomyces cerevisiae Ntg1 and Ntg2 proteins. This comparison shows that significant differences exist with respect to substrate specificity and kinetic parameters despite extensive structural conservation among the Nth homologues.

Clustered DNA damage, influence on damage excision by XRS5 nuclear extracts and Escherichia coli Nth and Fpg proteins

Ionizing radiation and radiomimetic anticancer agents induce clustered DNA damage, which are thought to reflect the biological severity. Escherichia coli Nth and Fpg and nuclear extracts from XRS5, a Chinese hamster ovary Ku-deficient cell line, have been used to study the influence on their substrate recognition by the presence of a neighboring damage or an abasic site on the opposite strand, as models of clustered DNA damage. These proteins were tested for their efficiency to induce a single-strand break on a (32)P-labeled oligonucleotide containing either an abasic (AP) site, dihydrothymine (DHT), 7,8-dihydro-8-oxo-2'deoxyguanine, or 7, 8-dihydro-8-oxo-2'deoxyadenine at positions 1, 3, or 5 base pairs 5' or 3' to either an AP site or DHT on the labeled strand. DHT excision is much more affected than cleavage of an AP site by the presence of other damage. The effect on DHT excision is greatest with a neighboring AP site, with the effect being asymmetric with Nth and Fpg. Therefore, this large inhibition of the excision of DHT by the presence of an opposite AP site may minimize the formation of double-strand breaks in the processing of DNA clustered damages.

Mutagenic specificity of imidazole ring-opened 7-methylpurines in M13mp18 phage DNA

The most abundant lesion formed in DNA upon modification with methylating agents 7-methylguanine, under alkaline conditions is converted into 2,6-diamino-4-hydroxy-5N-methyl-formamidopyrimidine (Fapy-7MeGua). We have previously shown that treatment of dimethylsulfate methylated DNA with NaOH creates mutagenic base derivatives leading to a 60-fold increase in the frequency of A-->G transitions and a 2-3-fold increase of G-->T and G-->C transversions. We have analyzed which lesions lead to these mutations. We compared mutagenic spectra in the lacZ gene of M13mp18 phage DNA modified with dimethylsulfate and NaOH after selective elimination of damaged bases from molecules used for transfection into SOS-induced E. coli. Partial elimination of Fapy-7MeGua from phage DNA performed by its digestion with formamidopyrimidine-DNA glycosylase resulted in a 2-3-fold decrease of G-->T and G-->C transversions. Selective depurination of methylated bases (9 h, 37 degrees C, pH 7.0) resulting in almost complete loss of 7MeAde as demonstrated by HPLC analysis of [3H]MNU alkylated phage DNA used as a probe, caused a dramatic, 9-fold decrease of A-->G transitions. Alkali-catalysed rearrangement of 7MeAde was followed by HPLC analysis of [3H]MNU alkylated poly(A) and poly(dA). After incubation of these oligonucleotides in NaOH, 7MeAde disappeared from both chromatograms, but only in polyA, 2 new peaks migrating with retention time different from that of 1MeAde, 3MeAde or 7MeAde were detected, suggesting formation of two rotameric forms of Fapy-7MeAde as observed for Fapy-7MeGua. Thus the miscoding lesion, giving rise to A-->G transitions derived from 7MeAde was Fapy-7MeAde. Fapy-7MeGua was at least an order of magnitude less mutagenic, but in SOS-induced cells it gave rise to G-->T and G-->C transversions.

Role of the N-terminal proline residue in the catalytic activities of the Escherichia coli Fpg protein

The Escherichia coli Fpg protein is a DNA glycosylase/AP lyase. It removes, in DNA, oxidized purine residues, including the highly mutagenic C8-oxo-guanine (8-oxoG). The catalytic mechanism is believed to involve the formation of a transient Schiff base intermediate formed between DNA containing an oxidized residue and the N-terminal proline of the Fpg protein. The importance and the role of this proline upon the various catalytic activities of the Fpg protein was examined by targeted mutagenesis, resulting in the construction of three mutant Fpg proteins: Pro-2 --> Gly (FpgP2G), Pro-2 --> Thr (FpgP2T), and Pro-2 --> Glu (FpgP2E). The formamidopyrimidine DNA glycosylase activities of FpgP2G and FpgP2T were comparable and accounted for 10% of the wild-type activity. FpgP2G and FpgP2T had barely detectable 8-oxoG-DNA glycosylase activity and produced minute Schiff base complex with 8-oxoG/C DNA. FpgP2G and FpgP2T mutants did not cleave a DNA containing preformed AP site but readily produced Schiff base complex with this substrate. FpgP2E was completely inactive in all the assays. The binding constants of the different mutants when challenged with a duplex DNA containing a tetrahydrofuran residue were comparable. The mutant Fpg proteins barely or did not complement in vivo the spontaneous transitions G/C --> T/A in E. coli BH990 (fpg mutY) cells. These results show the mandatory role of N-terminal proline in the 8-oxoG-DNA glycosylase activity of the Fpg protein in vitro and in vivo as well as in its AP lyase activity upon preformed AP site but less in the 2,6-diamino-4-hydroxy-5-N-methylformamidopyrimidine-DNA glycosylase activity.

Interactions of the human, rat, Saccharomyces cerevisiae and Escherichia coli 3-methyladenine-DNA glycosylases with DNA containing dIMP residues

In DNA, the deamination of dAMP generates 2'-deoxy-inosine 5'-monophosphate (dIMP). Hypoxanthine (HX) residues are mutagenic since they give rise to A.T-->G.C transition. They are excised, although with different efficiencies, by an activity of the 3-methyl-adenine (3-meAde)-DNA glycosylases from Escherichia coli (AlkA protein), human cells (ANPG protein), rat cells (APDG protein) and yeast (MAG protein). Comparison of the kinetic constants for the excision of HX residues by the four enzymes shows that the E.coli and yeast enzymes are quite inefficient, whereas for the ANPG and the APDG proteins they repair the HX residues with an efficiency comparable to that of alkylated bases, which are believed to be the primary substrates of these DNA glycosylases. Since the use of various substrates to monitor the activity of HX-DNA glycosylases has generated conflicting results, the efficacy of the four 3-meAde-DNA glycosylases of different origin was compared using three different substrates. Moreover, using oligo-nucleotides containing a single dIMP residue, we investigated a putative sequence specificity of the enzymes involving the bases next to the HX residue. We found up to 2-5-fold difference in the rates of HX excision between the various sequences of the oligonucleotides studied. When the dIMP residue was placed opposite to each of the four bases, a preferential recognition of dI:T over dI:dG, dI:dC and dI:dA mismatches was observed for both human (ANPG) and E.coli (AlkA) proteins. At variance, the yeast MAG protein removed more efficiently HX from a dI:dG over dI:dC, dI:T and dI:dA mismatches.

Enzymology of the repair of etheno adducts in mammalian cells and in Escherichia coli

Exocyclic adducts are generated in cellular DNA by reaction with epoxides that are formed metabolically from various industrial pollutants and by reaction with activated aldehydes that arise during membrane lipid peroxidation. The etheno (epsilon) derivatives of purine and pyrimidine bases, e.g. 3,N4-ethenocytosine, 1,N6-ethenoadenine, N2,3-ethenoguanine and 1,N2-ethenoguanine, are probably involved in carcinogenesis because they are highly mutagenic and genotoxic. Therefore, the repair processes that eliminate exocyclic adducts from DNA should play a crucial role in maintaining the stability of the genetic information. The DNA glycosylases implicated in the repair of etheno adducts have been identified. Human and Escherichia coli 3-methyladenine-DNA-glycosylases excise 1,N6-ethenoadenine residues. We have identified two homologous proteins present in human cells and E. coli that remove 3,N4-ethenocytosine residues by DNA glycosylase activity. The human enzyme is an activity of the mismatch-specific thymine-DNA glycosylase, while the bacterial enzyme is an activity of the double-stranded uracil-DNA glycosylase, i.e., the homologue of the human enzyme. The fact that 1,N6-ethenoadenine and 3,N4-ethenocytosine are recognized and efficiently excised by DNA glycosylases in vitro suggests that these enzymes may be responsible for the repair of these mutagenic lesions in vivo and may contribute importantly to genetic stability.

Clustered DNA damages induced in isolated DNA and in human cells by low doses of ionizing radiation

Clustered DNA damages-two or more closely spaced damages (strand breaks, abasic sites, or oxidized bases) on opposing strands-are suspects as critical lesions producing lethal and mutagenic effects of ionizing radiation. However, as a result of the lack of methods for measuring damage clusters induced by ionizing radiation in genomic DNA, neither the frequencies of their production by physiological doses of radiation, nor their repairability, nor their biological effects are known. On the basis of methods that we developed for quantitating damages in large DNAs, we have devised and validated a way of measuring ionizing radiation-induced clustered lesions in genomic DNA, including DNA from human cells. DNA is treated with an endonuclease that induces a single-strand cleavage at an oxidized base or abasic site. If there are two closely spaced damages on opposing strands, such cleavage will reduce the size of the DNA on a nondenaturing gel. We show that ionizing radiation does induce clustered DNA damages containing abasic sites, oxidized purines, or oxidized pyrimidines. Further, the frequency of each of these cluster classes is comparable to that of frank double-strand breaks; among all complex damages induced by ionizing radiation, double-strand breaks are only about 20%, with other clustered damage constituting some 80%. We also show that even low doses (0.1-1 Gy) of high linear energy transfer ionizing radiation induce clustered damages in human cells.

Mutagenic specificity of imidazole ring-opened 7-methylpurines in M13mp18 phage DNA

The most abundant lesion formed in DNA upon modification with methylating agents 7-methylguanine, under alkaline conditions is converted into 2,6-diamino-4-hydroxy-5N-methyl-formamidopyrimidine (Fapy-7MeGua). We have previously shown that treatment of dimethylsulfate methylated DNA with NaOH creates mutagenic base derivatives leading to a 60-fold increase in the frequency of A-->G transitions and a 2-3-fold increase of G-->T and G-->C transversions. We have analyzed which lesions lead to these mutations. We compared mutagenic spectra in the lacZ gene of M13mp18 phage DNA modified with dimethylsulfate and NaOH after selective elimination of damaged bases from molecules used for transfection into SOS-induced E. coli. Partial elimination of Fapy-7MeGua from phage DNA performed by its digestion with formamidopyrimidine-DNA glycosylase resulted in a 2-3-fold decrease of G-->T and G-->C transversions. Selective depurination of methylated bases (9 h, 37 degrees C, pH 7.0) resulting in almost complete loss of 7MeAde as demonstrated by HPLC analysis of [3H]MNU alkylated phage DNA used as a probe, caused a dramatic, 9-fold decrease of A-->G transitions. Alkali-catalysed rearrangement of 7MeAde was followed by HPLC analysis of [3H]MNU alkylated poly(A) and poly(dA). After incubation of these oligonucleotides in NaOH, 7MeAde disappeared from both chromatograms, but only in polyA, 2 new peaks migrating with retention time different from that of 1MeAde, 3MeAde or 7MeAde were detected, suggesting formation of two rotameric forms of Fapy-7MeAde as observed for Fapy-7MeGua. Thus the miscoding lesion, giving rise to A-->G transitions derived from 7MeAde was Fapy-7MeAde. Fapy-7MeGua was at least an order of magnitude less mutagenic, but in SOS-induced cells it gave rise to G-->T and G-->C transversions.

Substrate specificity of Deinococcus radiodurans Fpg protein

A DNA repair enzyme has recently been isolated from the ionizing radiation-resistant bacterium Deinococcus radiodurans [Bauche, C., and Laval, J. (1999) J. Bacteriol. 181, 262-269]. This enzyme is a homologue of the Fpg protein of Escherichia coli. We investigated the substrate specificity of this enzyme for products of oxidative DNA base damage using gas chromatography/isotope-dilution mass spectrometry and DNA substrates, which were either gamma-irradiated or treated with H(2)O(2)/Fe(III)-EDTA/ascorbic acid. Excision of purine lesions 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua), 4,6-diamino-5-formamidopyrimidine (FapyAde), and 8-hydroxyguanine (8-OH-Gua) was observed among 17 lesions detected in damaged DNA substrates. The extent of excision was determined as a function of enzyme concentration, time, and substrate concentration. FapyGua and FapyAde were excised with similar specificities from three DNA substrates, whereas 8-OH-Gua was the least preferred lesion. The results show that D. radiodurans Fpg protein and its homologue E. coli Fpg protein excise the same modified DNA bases, but the excision rates of these enzymes are significantly different. Formamidopyrimidines are preferred substrates of D. radiodurans Fpg protein over 8-OH-Gua, whereas E. coli Fpg protein excises these three lesions with similar efficiencies from various DNA substrates. Substrate specificities of these enzymes were also compared with that of Saccharomyces cerevisiae Ogg1 protein, which excises FapyGua and 8-OH-Gua, but not FapyAde.

Ultraviolet-B-induced damage to Escherichia coli Fpg protein

We investigated the effect of UVB light (290 < or = lambda < or = 320 nm) on the structure and enzymatic activities of Escherichia coli Fpg protein (2,6-diamino-4-hydroxy-5N-methylformamidopyrimidine-DNA glycosylase), a DNA repair enzyme containing a zinc finger motif and five chromophoric Trp residues. Irradiation with UVB light of air-saturated pH 7.4 buffered aqueous solutions of Fpg induces the formation of polymers as shown by sodium dodecyl sulfate polyacrylamide gel electrophoretic analysis. In argon-saturated solutions, polymer formation produces a precipitate. The polymerization quantum yield is 0.07 +/- 0.01 and 0.15 +/- 0.02 in air- and argon-saturated solutions, respectively. In the polymerized Fpg protein, second-derivative absorption spectroscopy indicates that three and one Trp residues are destroyed in air- and argon-saturated solutions, respectively. Polymers are devoid of all three activities of the Fpg protein, whereas the unpolymerized protein retains full activities. Matrix-assisted laser desorption/ionization experiments demonstrate that polymer formation is accompanied by the formation of short polypeptides containing the first 32 or 33 residues of the N-terminal domain. Theses polypeptides are most probably formed by the photolytic cleavage of Fpg protein induced by light absorption by the adjacent Trp-34 residue.

The type of DNA glycosylase determines the base excision repair pathway in mammalian cells

The base excision repair (BER) of modified nucleotides is initiated by damage-specific DNA glycosylases. The repair of the resulting apurinic/apyrimidinic site involves the replacement of either a single nucleotide (short patch BER) or of several nucleotides (long patch BER). The mechanism that controls the selection of either BER pathway is unknown. We tested the hypothesis that the type of base damage present on DNA, by determining the specific DNA glycosylase in charge of its excision, drives the repair of the resulting abasic site intermediate to either BER branch. In mammalian cells hypoxanthine (HX) and 1,N6-ethenoadenine (epsilonA) are both substrates for the monofunctional 3-methyladenine DNA glycosylase, the ANPG protein, whereas 7,8-dihydro-8-oxoguanine (8-oxoG) is removed by the bifunctional DNA glycosylase/beta-lyase 8-oxoG-DNA gly- cosylase (OGG1). Circular plasmid molecules containing a single HX, epsilonA, or 8-oxoG were constructed. In vitro repair assays with HeLa cell extracts revealed that HX and epsilonA are repaired via both short and long patch BER, whereas 8-oxoG is repaired mainly via the short patch pathway. The preferential repair of 8-oxoG by short patch BER was confirmed by the low efficiency of repair of this lesion by DNA polymerase beta-deficient mouse cells as compared with their wild-type counterpart. These data fit into a model where the intrinsic properties of the DNA glycosylase that recognizes the lesion selects the branch of BER that will restore the intact DNA template.

Repair of oxidized bases in the extremely radiation-resistant bacterium Deinococcus radiodurans

Deinococcus radiodurans is able to resist and survive extreme DNA damage induced by ionizing radiation and many other DNA-damaging agents. It is believed that it possesses highly efficient DNA repair mechanisms. To characterize the repair pathway of oxidized purines in this bacteria, we have purified, from crude extracts, proteins that recognize these oxidized bases. We report here that D. radiodurans possesses two proteins excising the oxidized purines (formamidopyrimidine and 8-oxoguanine) by a DNA glycosylase-a purinic/apyrimidine lyase mechanism. Moreover, one of those proteins is endowed with a thymine glycol DNA glycosylase activity. One of these proteins could be the homolog of the Escherichia coli Fpg enzyme, which confirms the existence of a base excision repair system in this bacteria.

Role of lysine-57 in the catalytic activities of Escherichia coli formamidopyrimidine-DNA glycosylase (Fpg protein)

The Escherichia coli Fpg protein is involved in the repair of oxidized residues. We examined, by targeted mutagenesis, the effect of the conserved lysine residue at position 57 upon the various catalytic activities of the Fpg protein. Mutant Fpg protein with Lys-57-->Gly (K57G) had dramatically reduced DNA glycosylase activity for the excision of 7,8-dihydro-8-oxo-guanine (8-oxoG). While wild type Fpg protein cleaved 8-oxoG/C DNA with a specificity constant ( k cat/ K M) of 0.11/(nM@min), K57G cleaved the same DNA 55-fold less efficiently. FpgK57G was poorly effective in the formation of Schiff base complex with 8-oxoG/C DNA. The efficiency in the binding of 8-oxoG/C DNA duplex for K57G mutant was decreased 16-fold. The substitution of Lys-57 for another basic amino acid Arg (K57R) had a slight effect on the 8-oxoG-DNA glycosylase activity and Schiff base formation. The DNA glycosylase activities of FpgK57G and FpgK57R using 2,6-diamino-4-hydroxy-5N-methylformamidopyrimidine residues as substrate were comparable to that of wild type Fpg. In vivo, the mutant K57G, in contrast to the mutant K57R and wild type Fpg, only partially restored the ability to prevent spontaneously induced transitions G/C-->T/A in E.coli BH990 ( fpg mutY ) cells. These results suggest an important role for Lys-57 in the 8-oxoG-DNA glycosylase activity of the Fpg protein in vitro and in vivo.

3,N4-ethenocytosine, a highly mutagenic adduct, is a primary substrate for Escherichia coli double-stranded uracil-DNA glycosylase and human mismatch-specific thymine-DNA glycosylase

Exocyclic DNA adducts are generated in cellular DNA by various industrial pollutants such as the carcinogen vinyl chloride and by endogenous products of lipid peroxidation. The etheno derivatives of purine and pyrimidine bases 3,N4-ethenocytosine (epsilonC), 1, N6-ethenoadenine (epsilonA), N2,3-ethenoguanine, and 1, N2-ethenoguanine cause mutations. The epsilonA residues are excised by the human and the Escherichia coli 3-methyladenine-DNA glycosylases (ANPG and AlkA proteins, respectively), but the enzymes repairing epsilonC residues have not yet been described. We have identified two homologous proteins present in human cells and E. coli that remove epsilonC residues by a DNA glycosylase activity. The human enzyme is an activity of the mismatch-specific thymine-DNA glycosylase (hTDG). The bacterial enzyme is the double-stranded uracil-DNA glycosylase (dsUDG) that is the homologue of the hTDG. In addition to uracil and epsilonC-DNA glycosylase activity, the dsUDG protein repairs thymine in a G/T mismatch. The fact that epsilonC is recognized and efficiently excised by the E. coli dsUDG and hTDG proteins in vitro suggests that these enzymes may be responsible for the repair of this mutagenic lesion in vivo and be important contributors to genetic stability.

Antimutagenic role of base-excision repair enzymes upon free radical-induced DNA damage

As a consequence of oxidative stress, reactive oxygen species are generated in the cells. They interact with DNA and induce various modifications. Among them, oxidised purines (such as C8-oxoguanine and purines whose imidazole ring is opened), oxidised pyrimidines (such as thymine and cytosine glycols, ring saturated and fragmented pyrimidines), ethenobases and hypoxanthine. These various lesions have either miscoding properties or are blocks for DNA and RNA polymerases during replication and transcription, respectively. Most of these lesions are repaired by the base excision pathway in which the first step is mediated by specific DNA glycosylases. We review the various glycosylases involved in the repair of oxidised bases in Escherichia coli. The Fpg protein (formamidopyrimidine-DNA glycosylase) contains a zinc finger and excises oxidised purines whereas the Nth protein excises oxidised pyrimidines. The Nei protein excises a comparable spectra of pyrimidines and is believed to act as a back up enzyme to the Nth protein. The hypoxanthine-DNA glycosylase excises hypoxanthine residue and is one of the various activities of the AlkA protein (including formyluracil and ethenopurines residues). The Nfo protein was shown to have a novel activity that incises 5' to an alpha-deoxyadenosine residue (the anomer of deoxyadenosine formed by gamma-irradiation). The mechanism of action of the Fpg and Nth proteins are discussed. The properties of the human counterpart of the Fpg and Nth proteins the hNth and OGG1 proteins, respectively are also reviewed.

The ring fragmentation product of thymidine C5-hydrate when present in DNA is repaired by the Escherichia coli Fpg and Nth proteins

Various forms of oxidative stress, including gamma-radiolysis and UV irradiation, result in the formation of damaged bases. (5R)-Thymidine C5-hydrate is one of several modified nucleosides produced from thymidine under these conditions. N-(2-Deoxy-beta-D-erythro-pentofuranosyl)-N-3-[(2R)-hydroxyisobutyric acid]urea or alphaRT is the respective fragmentation product formed from (5R)-thymidine C5-hydrate upon hydrolysis. This modified nucleoside has potential mutagenic or lethal properties. No enzymatic activity responsible for the removal of alphaRT has been identified. We report here that when present in DNA, alphaRT is a substrate for two purified enzymes from Escherichia coli involved in the repair of oxidized bases: the Nth and the Fpg proteins. The Fpg protein removes the alphaRT lesion more efficiently than the Nth protein. This is the first example of efficient excision of a ring-opened form of a pyrimidine by the Fpg protein. The high efficacy of the Fpg protein suggests that it is likely to be involved in vivo in the excision of alphaRT. The kinetics of the reaction of the Fpg protein with DNA containing alphaRT suggest substrate inhibition. Duplex oligodeoxynucleotides containing alphaRT positioned opposite T, dG, dC, and dA were cleaved efficiently by both enzymes, although the profiles of activity of the two enzymes were different. The Nth enzyme preferentially excises alphaRT when opposite a dG, followed by alphaRT.dA, alphaRT. T, and alphaRT.dC. For the Fpg protein, the order is alphaRT.dC >/= alphaRT.dG approximately alphaRT.T > alphaRT.dA. Moreover, we show that human cell extract exhibits an activity that excises alphaRT from an oligonucleotide, suggesting that human homologues of the Nth and/or Fpg proteins could be involved in repair of this lesion in human cells.

The multifaceted roles of nitric oxide in cancer

The roles of nitric oxide (NO) in numerous disease states have generated considerable discussion over the past several years. NO has been labeled as the causative agent in different pathophysiological mechanisms, yet appears to protect against various chemical species such as those generated under oxidative stress. Similarly, NO appears to exert a dichotomy of effects within the multistage model of cancer. Chronic inflammation can lead to the production of chemical intermediates, among them NO, which in turn can mediate damage to DNA. Yet, NO also appears to be critical for the tumoricidal activity of the immune system. Furthermore, NO can also have a multitude of effects on other aspects of tumor biology, including angiogenesis and metastasis. This report will discuss how the chemistry of NO may impact the initiation and progression stages of cancer.

Effect of single mutations on the structural dynamics of a DNA repair enzyme, the Escherichia coli formamidopyrimidine-DNA glycosylase--a fluorescence study using tryptophan residues as reporter groups

The effects on the structure dynamics of the Escherichia coli wild-type formamidopyrimidine-DNA glycosylase (Fpg) protein of the single mutations Lys57-->Gly (FpgK57G), Pro2-->Gly (FpgP2G) and Pro2-->Glu (FpgP2E) were studied by fluorescence techniques, namely: lifetime measurements and acrylamide quenching of the fluorescence of Trp residues. The fluorescence decays of Fpg and its mutant forms were analysed by the maximum-entropy method and lifetime distributions in the range 200 ps to 9 ns were obtained. The lifetime distribution profiles of FpgK57G, FpgP2G and FpgP2E are different from that of wild-type Fpg. Both dynamic and static quenching by acrylamide were observed for all the proteins. At 20 degrees C, the bimolecular collisional quenching rate constant of the FpgP2E fluorescence by acrylamide was only 0.8 M(-1) s(-1) as compared to about 1.4 M(-1) s(-1) for the three other proteins. At 6 degrees C, all the spectroscopic properties of these four proteins are about the same. The analysis of experimental data demonstrates that all three mutations induce a structural reorganization of the Fpg protein. However, only the P2E mutation lead to a reduced accessibility of some Trp residues to acrylamide quenching. It is concluded that the single P2E replacement induces a conformational change leading to a more rigid globular structure as opposed to the wild type and K57G and P2G mutations. The influence of the single mutations on the enzyme activities of the Fpg protein is discussed.

Specific binding of a designed pyrrolidine abasic site analog to multiple DNA glycosylases

In the base excision DNA repair pathway, DNA glycosylases recognize damaged bases in DNA and catalyze their excision through hydrolysis of the N-glycosidic bond. Attempts to understand the structural basis for DNA damage recognition by DNA glycosylases have been hampered by the short-lived association of these enzymes with their DNA substrates. To overcome this problem, we have employed an approach involving the design and synthesis of inhibitors that form stable complexes with DNA glycosylases, which can then be studied biochemically and structurally. We have previously reported that double-stranded DNA containing a pyrrolidine abasic site analog (PYR) forms an extremely stable complex with the DNA glycosylase AlkA and potently inhibits the reaction catalyzed by the enzyme (Schärer, O. D., Ortholand, J.-Y., Ganesan, A., Ezaz-Nikpay, K., and Verdine, G. L. (1995) J. Am. Chem. Soc. 117, 6623-6624). Here we investigate the interaction of this inhibitor with a variety of additional DNA glycosylases. With the exception of uracil DNA glycosylase all the glycosylases tested bind specifically to PYR-containing oligonucleotides. By comparing the interaction of DNA glycosylases with PYR and the structurally related tetrahydrofuran abasic site analog, we assess the importance of the positively charged ammonium group of the pyrrolidine in binding to the active site of these enzymes. Such a general inhibitor of DNA glycosyases provides a valuable tool to study stable complexes of these enzymes bound to substrate-like molecules.

Activity of Escherichia coli DNA-glycosylases on DNA damaged by methylating and ethylating agents and influence of 3-substituted adenine derivatives

Methylating and ethylating agents are used in the chemical industry and produced during tobacco smoking. They generate DNA base damage whose role in cancer induction has been documented. Alkylated bases are repaired by the base excision repair pathway. We have established the repair efficiency of methylated and ethylated bases by various Escherichia coli repair proteins, namely 3-methyladenine-DNA-glycosylase I (TagA protein), which excises 3-methyladenine and 3-methylguanine, 3-methyladenine-DNA-glycosylase II (AlkA protein), which has a broad substrate specificity including 3- and 7-alkylated purines and the formamidopyrimidine(Fapy)-DNA-glycosylase (Fpg protein) repairing imidazole ring-opened 7-methylguanine. The comparison of the Km values of these various enzymes showed that methylated bases were excised more efficiently than ethylated bases. Several 3-alkyladenine derivatives have been synthesized and examined for their ability to inhibit the activity of the various repair proteins. We have shown that 3-ethyl-, 3-propyl-, 3-butyl- and 3-benzyladenine were much more efficient inhibitors of TagA protein than 3-methyladenine. The inhibitory effect was increased with the increase of the size of alkyl-group and IC50 for 3-benzyladenine was 0.4 +/- 0.1 microM as compared to 1.5 +/- 0.3 mM for 3-methyladenine. These compounds inhibited neither the AlkA protein nor human 3-methyladenine-DNA-glycosylase (ANPG protein). Moreover, 3-hydroxyethyladenine did not affect the activity of any of these enzymes. Taken together, these results suggest that hydrophobic interactions are involved in the mechanism of inhibition and/or recognition and excision of alkylated purines by TagA protein.

Fpg protein releases a ring-opened N-7 guanine adduct from DNA that has been modified by sulfur mustard

Transfection of the Escherichia coli fpg gene into Chinese hamster ovary cells has been reported to enhance survival after exposure to aziridine (C. Cussac and F.Laval, 1996, Nucleic Acids Res., 24, 1742-1746). This result suggests that Fpg protein protects cells from toxicity by removing ring-opened N-7 guanine adducts from DNA, and raises the possibility that Fpg protein would offer protection from other agents that alkylate the N-7 position of guanine. Since the major adduct formed by sulfur mustard in DNA is 7-hydroxyethyl-thioethylguanine (HETEG), we have investigated the action of Fpg protein on the ring-opened form of this adduct (ro-HETEG). A substrate containing ro-HETEG was prepared by alkaline treatment of DNA modified by [14C]sulfur mustard. Fpg protein purified from an over-producing strain of E. coli released ro-HETEG from this substrate in an enzyme- and time-dependent manner, and at a rate that is similar to that at which it releases ring-opened 7-methylguanine. Thus, Fpg protein acts efficiently on ro-HETEG, and may offer some protection against the toxic action of sulfur mustard.

Effects of nitrous acid treatment on the survival and mutagenesis of Escherichia coli cells lacking base excision repair (hypoxanthine-DNA glycosylase-ALK A protein) and/or nucleotide excision repair

Deoxyinosine occurs in DNA by spontaneous deamination of adenine or by incorporation of dITP during replication. Hypoxanthine residues (HX) are mutagenic and give rise to A-T-->G-C transition. They are substrates for the Escherichia coli product of the alkA gene, the 3-methyl-adenine-DNA glycosylase II (ALK A protein). In mammalian cells and in yeast, HX is excised by the counterpart of ALK A protein, the ANPG or the MAG proteins respectively. We have investigated in vivo the contribution of the alkA gene to counteract the lethal and/or mutagenic effects of HX residues induced by nitrous acid treatment. Using an E.coli strain allowing the detection of A-T-->G-C transition, we show that the alkA mutant has a slightly increased spontaneous rate of mutation and about the same sensitivity when treated with HNO2 as compared with the wild-type strain. Using the E.coli alkA mutant carrying a multicopy plasmid expressing the ALK A protein or the ANPG protein, we barely observe any effect of HNO2 treatment on sensitivity and mutation rate of the bacteria. In contrast, the same experiment performed with a uvrA- strain, deficient in nucleotide excision repair (NER), shows that this mutant is extremely sensitive to HNO2 treatment. Furthermore, the sensitivity and the spontaneous mutation rate observed in the double mutant alkA- uvrA- are almost identical to those of the uvrA- mutant. Hence, NER has the major role in vivo for the repair of lethal and mutagenic lesions induced by HNO2.

Gene-specific nuclear and mitochondrial repair of formamidopyrimidine DNA glycosylase-sensitive sites in Chinese hamster ovary cells

This study examines the capacity of a mammalian cell to repair, at the gene level, DNA base lesions generated by photoactivation of acridine orange. Chinese hamster ovary fibroblasts were exposed to acridine orange and visible light, and gene-specific DNA repair was measured in the dihydrofolate reductase (DHFR) gene and in the mitochondrial genome. DNA lesions were recognized by Escherichia coli formamidepyrimidine-DNA glycosylase (FPG) which removes predominantly 8-oxodG and the corresponding formamidopyrimidine ring opened bases, and subsequently cleaves the DNA at the resulting apurinic site. FPG-recognized DNA lesions increased linearly with increasing photo-activation of AO, while cell survival was not affected by light alone and was negligibly affected by preincubation with AO in the dark. The frequency of induction of FPG-sensitive DNA damage by photoactivation of AO was similar in the transcribed and non-transcribed nuclear DNA as well as in the mitochondrial DNA. FPG-sensitive sites in the DHFR gene were repaired quickly, with 84% of adducts repaired within 4 h. The lesion frequency, kinetics and percent of repair of non-transcribed genomic DNA did not differ significantly from repair in the active DHFR gene up to 1 h postexposure. At late time points, transcribed DNA was repaired faster than the non-transcribed DNA. Mitochondrial DNA was efficiently repaired, at a rate similar to that in the active nuclear DNA.

Excision of DNA adducts of nitrogen mustards by bacterial and mammalian 3-methyladenine-DNA glycosylases

Nitrogen mustards are among the DNA alkylating agents most widely used in chemotherapy. The homogeneous Escherichia coli AlkA protein (3-methyladenine-DNA glycosylase II) is shown to excise damaged guanine and adenine bases from DNA modified by mechlorethamine, uracil mustard, phenylalanine mustard and chlorambucil, and less efficiently acridine mustard adducts. Homogeneous recombinant human and rat 3-methyladenine-DNA glycosylases excise adducts formed by nitrogen mustards less efficiently than the AlkA protein. In addition to the in vitro excision of adducts, the AlkA protein eliminates cytotoxic mechlorethamine adducts from DNA in vivo.

Role of DNA repair enzymes in the cellular resistance to oxidative stress

Oxidative stress occurs in cells when the equilibrium between prooxidant and antioxidant species is broken in favor of the prooxidant state. It is due to reactive oxygen species (ROS) generated either by the cellular metabolism such as phagocytosis, mitochondrial respiration, xenobiotic detoxification, or by exogenous factors such as ionizing radiation or chemical compounds performing red-ox reactions. Some ROS are extremely reactive and interact with all the macromolecules including lipids, nucleic acids and proteins. Cells have numerous defence systems to counteract the deleterious effects of ROS. Proteins and small molecules specifically eliminate ROS when they are formed. There are three species of superoxyde dismutases which transform the superoxyde anion O2- in hydrogen peroxyde H2O2 which in turn will be destroyed by peroxysomal catalase or by various peroxydases. There are numerous small molecules in the cell such as glutathion, alpha-tocopherol, vitamines A and C, melanine, etc. which are antioxydant molecules. ROS escaping destruction generate various lesions in DNA such as base modifications, degradation products of deoxyribose, chain breaks. These various lesions have been characterized and it is possible to quantitate them in the DNA of cells which have been irradiated or treated by free radical generating systems. The biological properties of the bases modified by ROS have been established. For example C8-hydroxyguanine (8-oxoG) is promutagenic since, if present in DNA during replication, it leads to incorporation of dAMP residues, leading to transversion mutation (GC-->TA). Purines whose imidazole ring is opened (Fapy residues) are stops for the DNA polymerase during DNA replication and are therefore potentially lethal lesions for the cell. Oxidized pyrimidines have comparable coding properties. Efficient DNA repair mechanisms remove these oxidized bases. In Escherichia coli cells, endonuclease III (NTH protein) and endonuclease VIII (NEI protein) excise many oxidized pyrimidines, whereas the FPG protein (formamidopyrimidine-DNA-glycosylase) eliminates 8-oxoG and Fapy lesions. Besides its DNA glycosylase activity, the protein FPG has a beta-lyase activity incising DNA at abasic site by a beta-delta elimination mechanism, and a dRPase activity. The FPG protein has a zinc finger motive which is mandatory for the recognition of its substrate. Mammalian cells have similar DNA repair proteins and it should be emphazized that there is conservation of the different functions and in most cases a remarquable homology of the amino acids sequences from E. coli to man.

Escherichia coli, Saccharomyces cerevisiae, rat and human 3-methyladenine DNA glycosylases repair 1,N6-ethenoadenine when present in DNA

The human carcinogen vinyl chloride is metabolized in the liver to reactive intermediates which generate various ethenobases in DNA. It has been reported that 1,N6-ethenoadenine (epsilon A) is excised by a DNA glycosylase present in human cell extracts, whereas protein extracts from Escherichia coli and yeast were devoid of such an activity. We confirm that the human 3-methyladenine-DNA glycosylase (ANPG protein) excises epsilon A residues. This finding was extended to the rat (ADPG protein). We show, at variance with the previous report, that pure E.coli 3-methyladenine-DNA glycosylase II (AlkA protein) as well as its yeast counterpart, the MAG protein, excise epsilon A from double stranded oligodeoxynucleotides that contain a single epsilon A. Both enzymes act as DNA glycosylases. The full length and the truncated human (ANPG 70 and 40 proteins, respectively) and the rat (ADPG protein) 3-methyladenine-DNA glycosylases activities towards epsilon A are 2-3 orders of magnitude more efficient than the E.coli or yeast enzyme for the removal of epsilon A. The Km of the various proteins were measured. They are 24, 200 and 800 nM for the ANPG, MAG and AlkA proteins respectively. These three proteins efficiently cleave duplex oligonucleotides containing epsilon A positioned opposite T, G, C or epsilon A. However the MAG protein excises A opposite cytosine much faster than opposite thymine, guanine or adenine.

Mapping of copper/hydrogen peroxide-induced DNA damage at nucleotide resolution in human genomic DNA by ligation-mediated polymerase chain reaction

The ligation-mediated polymerase chain reaction was used to map the frequency of reactive oxygen species-induced DNA damage at nucleotide resolution in genomic DNA purified from cultured human male fibroblasts. Damaged pyrimidine and purine bases were recognized and cleaved by the Nth and Fpg proteins from Escherichia coli, respectively. Strand breaks and modified bases were induced in vitro by copper ion-mediated reduction of hydrogen peroxide in the presence of ascorbate; reactant concentrations were adjusted to induce lesions at a frequency of 1 per 2-3 kilobases in purified genomic DNA. Glyoxal gel analysis demonstrated that the ratio of induced strand breaks to induced base damage was 0.8/2.7 in DNA dialyzed extensively to remove adventitious transition metal ions. Ligation-mediated polymerase chain reaction analysis of the damage frequency in the promoter region of the transcriptionally active phosphoglycerate kinase (PGK 1) gene revealed that (Cu(II)/ascorbate/H2O2 caused DNA base damage by a sequence-dependent mechanism, with the 5' bases of d(pGn) and d(pCn) being damage hot spots, as were the most internal guanines of d(pGGGCCC) and d(pCCCGGG). Since base damage occurs after formation of a DNA-Cu(I)-H2O2 complex, these data suggest that the local DNA sequence affects formation of DNA-Cu(I)-H2O2 complexes and/or the efficiency of base oxidation during resolution of this complex.

HU protein of Escherichia coli binds specifically to DNA that contains single-strand breaks or gaps

In this study, we have identified a protein in Escherichia coli that specifically binds to double-stranded DNA containing a single-stranded gap of one nucleotide. The gap-DNA binding (GDB) protein was purified to apparent homogeneity. The analysis of the amino-terminal sequencing of the GDB protein shows two closely related sequences we identify as the alpha and beta subunits of the HU protein. Furthermore, the GDB protein is not detected in the crude extract of an E. coli double mutant strain hupA hupB that has no functional HU protein. These results led us to identify the GDB protein as the HU protein. HU binds strongly to double-stranded 30-mer oligonucleotides containing a nick or a single-stranded gap of one or two nucleotides. Apparent dissociation constants were measured for these various DNA duplexes using a gel retardation assay. The KD(app) values were 8 nM for the 30-mer duplex that contains a nick and 4 and 2 nM for those that contain a 1-or a 2-nucleotide gap, respectively. The affinity of HU for these ligands is at least 100-fold higher than for the same 30-mer DNA duplex without nick or gap. Other single-stranded breaks or gaps, which are intermediate products in the repair of abasic sites after incision by the Fpg, Nth, or Nfo proteins, are also preferentially bound by the HU protein. Due to specific binding to DNA strand breaks, HU may play a role in replication, recombination, and repair.

The Fpg protein, a DNA repair enzyme, is inhibited by the biomediator nitric oxide in vitro and in vivo

Nitric oxide has been shown to be a mediator molecule in the regulation of many physiological functions. However, this small diatomic molecule in the presence of O2 generates reactive intermediates which modify DNA bases and inactive enzymes at high concentrations (100 microM). We report that NO generated by 1,1-diethyl-2-hydroxy-2-nitrosohydrazine (DEA/NO, Et2NN(O)NO-Na+), a compound known to release NO in a predictable manner, caused irreversible damage at physiological concentrations to the zinc finger-containing DNA repair enzyme formamidopyrimidine-DNA glycolyase (Fpg protein). The inhibition of the enzyme activity was DEA/NO dose and time dependent with IC50s with respect to total NO released from this compound of approximately 110 and approximately 120 mumol/l respectively. This inhibitory effect by P3 was not reversible over time in the presence of reducing agents and/or Zn2+. Nitrite and diethylamine, the nitrogenous products of the decomposition of DEA/NO, did not inhibit the enzyme. The presence of 500 micrograms/ml bovine serum albumin did not protect the protein from the inhibitory effects of DEA/NO, however, the presence of 10 mM cysteine did dramatically abate the inhibition of the Fpg protein by DEA/NO. Other DNA glycosylases tested were not inhibited by exposure to these concentrations of NO. These results, together with reports of site-directed mutagenesis of this protein, suggest that the cysteine residues contained within the zinc finger motif of the Fpg protein are the primary sites of NO interaction. Our studies were then extended to intact cells. The Fpg protein activity was decreased following treatment in vivo when Escherichia coli MH321 (acr A-) cells were treated with DEA/NO. Furthermore, the Fapy-DNA glycosylase activity in H4 cells, a rat hepatoma line, was decreased when intact cells were incubated with DEA/NO.

Reaction kinetics for nitrosation of cysteine and glutathione in aerobic nitric oxide solutions at neutral pH. Insights into the fate and physiological effects of intermediates generated in the NO/O2 reaction

The critical regulatory function of nitric oxide (NO) in many physiologic processes is well established. However, in an aerobic aqueous environment NO is known to generate one or more reactive and potentially toxic nitrogen oxide (NOx) metabolites. This has led to the speculation that mechanisms must exist in vivo by which these reactive intermediates are detoxified, although the nature of these mechanisms has yet to be elucidated. This report demonstrates that among the primary bioorganic products of the reaction of cellular constituents with the intermediates of the NO/O2 reaction are S-nitrosothiol (S-NO) adducts. Anaerobic solutions of NO are not capable of nitrosating cysteine or glutathione, while S-NO adducts of these amino acids are readily formed in the presence of O2 and NO. Investigation of the kinetics for the formation of these S-NO adducts has revealed a rate equation of d[RSNO]/dt = kSNO[NO]2[O2], where kSNO = (6 +/- 2) x 10(6) M-2S-1, a value identical to that for the formation of reactive intermediates in the autoxidation of NO. Competition studies performed with a variety of amino acids, glutathione, and azide have shown that cysteine residues have an affinity for the NOx species that is 3 orders of magnitude greater than that of the nonsulfhydryl amino acids, and > 10(6) times greater than that of the exocyclic amino groups of DNA bases. The dipeptide alanyltyrosine reacts with the intermediates of the NO/O2 reaction with an affinity 150 times less than that of the sulfhydryl-containing compounds. Furthermore, Chinese hamster V79 lung fibroblasts depleted of glutathione display enhanced cytotoxicity on exposure to NO.(ABSTRACT TRUNCATED AT 250 WORDS)

Excision of hypoxanthine from DNA containing dIMP residues by the Escherichia coli, yeast, rat, and human alkylpurine DNA glycosylases

The deamination of adenine residues in DNA generates hypoxanthine, which is mutagenic since it gives rise to an A.T to G.C transition. Hypoxanthine is removed by hypoxanthine DNA glycosylase activity present in Escherichia coli and mammalian cells. Using polydeoxyribonucleotides or double-stranded synthetic oligonucleotides that contain dIMP residues, we show that this activity in E. coli is associated with the 3-methyladenine DNA glycosylase II coded for by the alkA gene. This conclusion is based on the following facts: (i) the two enzymatic activities have the same chromatographic behavior on various supports and they have the same molecular weight, (ii) both are induced during the adaptive response, (iii) a multicopy plasmid bearing the alkA gene overproduces both activities, (iv) homogeneous preparation of AlkA has both enzymatic activities, (v) the E. coli alkA- mutant does not show any detectable hypoxanthine DNA glycosylase activity. Under the same experimental conditions, but using different substrates, the same amount of AlkA protein liberates 1 pmol of 3-methyladenine from alkylated DNA and 1.2 fmol of hypoxanthine from dIMP-containing DNA. The Km for the latter substrate is 420 x 10(-9) M as compared to 5 x 10(-9) M for alkylated DNA. Hypoxanthine is released as a free base during the reaction. Duplex oligodeoxynucleotides containing hypoxanthine positioned opposite T, G, C, and A were cleaved efficiently. ANPG protein, APDG protein, and MAG protein--the 3-methyladenine DNA glycosylases of human, rat, and yeast origin, respectively--were also able to release hypoxanthine from various DNA substrates containing dIMP residues. The mammalian enzyme is by far the most efficient hypoxanthine DNA glycosylase of all the enzymes tested.

Cloning of the Escherichia coli radC gene: identification of the RadC protein

1. The DNA sequence of the radC gene suggests an open reading frame of 297-bp. 2. To identify the gene product, radC was subcloned in an expression vector, pKK223-3 and the RadC protein identified by the maxicell method as a polypeptide of approximately 11 kDa.

Substrate specificity of the Escherichia coli endonuclease III: excision of thymine- and cytosine-derived lesions in DNA produced by radiation-generated free radicals

The excision of modified bases from DNA by Escherichia coli endonuclease III was investigated. Modified bases were produced in DNA by exposure of dilute buffered solutions of DNA to ionizing radiation under oxic or anoxic conditions. The technique of gas chromatography/mass spectrometry (GC/MS) was used to identify and quantify 16 pyrimidine- and purine-derived DNA lesions. DNA substrates were incubated either with the native enzyme or with the heat-inactivated enzyme. Subsequently, DNA was precipitated. Pellets were analyzed by GC/MS after hydrolysis and derivatization. Supernatant fractions were analyzed after derivatization without hydrolysis. The results provided unequivocal evidence for the excision by E. coli endonuclease III of a number of thymine- and cytosine-derived lesions from DNA. These were 5,6-dihydrothymine, 5-hydroxy-5-methylhydantoin, thymine glycol, 5-hydroxy-6-hydrothymine, 5,6-dihydrouracil, alloxan, uracil glycol, and 5-hydroxy-6-hydrouracil. None of the purine-derived lesions was excised by endonuclease III. The present work extends the substrate specificity of E. coli endonuclease III to another thymine-derived and four cytosine-derived lesions. It is the first investigation of the substrate specificity of this repair enzyme in the context of a large number of pyrimidine- and purine-derived lesions in DNA.

Cleavage and binding of a DNA fragment containing a single 8-oxoguanine by wild type and mutant FPG proteins

A 34-mer oligonucleotide containing a single 7,8-dihydro-8-oxoguanine (8-OxoG) residue was used to study the enzymatic and DNA binding properties of the Fpg protein from E. coli. The highest rates of incision of the 8-OxoG containing strand by the Fpg protein were observed for duplexes where 8-OxoG was opposite C (*G/C) or T (*G/T). In contrast, the rates of incision of duplexes containing 8-OxoG opposite G (*G/G) and A (*G/A) were 5-fold and 200-fold slower. Gel retardation studies showed that the Fpg protein had a strong affinity for duplexes where the 8-OxoG was opposite pyrimidines and less affinity for duplexes where the 8-OxoG was opposite purines. KDapp values were 0.6 nM (*G/C), 1.0 nM (*G/T), 6.0 nM (*G/G) and 16.0 nM (*G/A). The Fpg protein also binds to unmodified (G/C) duplex and a KDapp of 90 nM was measured. The cleavage and binding of the (*G/C) duplex were also studied using bacterial crude lysates. Wild type E. coli crude extract incised the 8-OxoG containing strand and formed a specific retardation complex with the (*G/C) duplex. These two reactions were mediated by the Fpg protein, since they were not observed with a crude extract from a bacterial strain whose fpg gene was inactivated. Furthermore, we have studied the properties of 6 mutant Fpg proteins with Cys-->Gly mutations. The results showed that the 2 Fpg proteins with Cys-->Gly mutations outside the zinc finger sequence cleaved the 8-OxoG containing strand, formed complexes with the (*G/C) duplex and suppressed the mutator phenotype of the fpg-1 mutant. In contrast, the 4 Fpg proteins with Cys-->Gly mutations within the zinc finger motif neither cleave nor bind the (*G/C) duplex, nor do these proteins suppress the fpg-1 mutator phenotype.